CN106878374B

CN106878374B - Communication network for vehicle and subscriber device of the communication network

Info

Publication number: CN106878374B
Application number: CN201611142957.5A
Authority: CN
Inventors: J-F·圣艾蒂安; J·洛佩兹
Original assignee: Airbus Operations SAS; Airbus SAS
Current assignee: Airbus Operations SAS; Airbus SAS
Priority date: 2015-12-14
Filing date: 2016-12-12
Publication date: 2020-02-07
Anticipated expiration: 2036-12-12
Also published as: US20170171112A1; CN106878374A; FR3045256A1; FR3045256B1; US10193830B2

Abstract

A communication network onboard a vehicle and a subscriber to the communication network. Deterministic ethernet using virtual links includes: a first receiver (20 a); a first emitter (22 a); a first memory (19) provided to record a configuration table relating to a set of virtual links that a subscriber can receive and/or forward; and a processing unit configured to implement: at least one application (18); a receiving function (12) configured to receive data frames received by the first receiver (20a), for accepting the reception and transmitting the frames to the screening function (16) only if the data frames correspond to virtual links of the set belonging to the virtual links; the screening function (16) configured to transmit the received data frames to an application (18) and/or to a transmitting function (14); and a transfer function (14) configured to send the received data frame to the first transmitter (22a) while complying with a BAG constraint associated with the corresponding virtual link.

Description

Communication network for vehicle and subscriber device of the communication network

Technical Field

The present invention relates to the field of communication networks, and in particular to the field of communication networks installed in aircraft.

Background

Aircraft typically include one or more onboard communication networks provided to allow communication between onboard equipment, particularly onboard computers. In order to meet the regulatory requirements of aircraft certification, the communications network on board should be deterministic, that is, it should allow the transmission of information from one or more transmitting devices signed to the communications network to one or more receiving devices signed to the communications network, while having a transmission duration less than a predetermined duration and without losing information through the network. Section 7 of the ARINC 664 standard defines an installed avionics communications network based on the certainty of full duplex switched ethernet technology. Such a network may for example correspond to

A communication network. In a network conforming to part 7 of the ARINC 664 standard, each device is connected to a communications switch and communications between different devices pass through virtual links defined at the time of network definition and configuration. A virtual link is defined between the transmitting device and one or more receiving devices via one or more network switches. Each virtual link traverses a determined path in the network. A passband is assigned to each virtual link and the routing of the different virtual links of the network is implemented such that the sum of the passbands assigned to the virtual links via the same physical link does not exceed the passbands supported by the physical link. This is necessary to ensure physical certainty. When a transmitting device, which is signed up to the communication physics, wishes to transmit information to one or more receiving devices, it sends this information in data frames on a virtual link, the receiving device or devices being the destination of the virtual link. The transmission of data frames by the transmitting device is implemented subject to the time-shaping constraints (traffic shaping) of each virtual link. For a given virtual link, these constraints correspond in particular to the time interval between two successive transmissions of data packets on the virtual link, these data packets corresponding to a set of data frames. This time interval is commonly referred to as a BAG (bandwidth allocation gap). The BAG is defined at the communication physical design time for each virtual link. When the virtual link passes through the switch, the switch receives data frames corresponding to the virtual link on the first physical link and retransmits the data frames on the first physical link. Retransmission of data frames corresponding to different virtual links sharing the second physical link over the second physical link is achieved asynchronously based on receipt of different data frames by the switch. For a given virtual link, a "jitter" phenomenon corresponding to the time shift is produced by the switch between successive transmissions of packets on the virtual link, relative to the BAG defined for the virtual link. The role of each switch that is virtually linked through increases jitter phenomena, and time shifts due to different switches being traversed may accumulate. In receiving the virtual by the receiving subscriberWhen a link is to be made, the recipient subscriber performs a function, called traffic management, which among other things enables time validation of packets received on the virtual link. The function verifies, among other things, whether the jitter is less than the maximum jitter value permitted for the virtual link. In fact, in case the network is a deterministic network, the jitter value should always be smaller than this maximum allowable jitter value. In the presentation step of the certainty of the communication network, it is necessary to evaluate the maximum jitter value at the time of reception of each virtual link by the recipient subscriber in order to verify whether this maximum jitter value is less than the maximum jitter value permitted for this virtual link. The presentation is as complex as the large number of virtual links and the large number of switches traversed by the virtual links. The presentation also provides for calculating, for each virtual link, a transmission time over the virtual link between the transmitting subscriber and each receiving subscriber. This calculation is complex, considering the jitter caused by traversing different switches.

All communications between the devices are defined beforehand by the definition of virtual links, so as to allow the configuration of the switches: each switch includes a virtually linked functional configuration table that is switched by the switch. The configuration of each switch is loaded into the table prior to use. Switches typically include a large number of communication ports, for example 24 ports for some switches. Redundancy of the switch is also provided in order to avoid the failure of the switch causing the impossibility of communication between these devices: the communication network is replicated over two groups of switches (where the switches are similarly connected to each other). Each subscriber of the communication network is connected on the one hand to the switch of a first of the two switch groups and on the other hand to the corresponding switch of the other switch group. Modern aircraft may therefore include a large number of switches, for example 14 switches on some aircraft. The result is a desire for reduced weight, volume and power consumption in order to improve the performance of the aircraft.

Disclosure of Invention

The object of the present invention is, inter alia, to propose a solution to these problems. The invention relates to a subscriber of a communication network onboard a vehicle, the communication network being a deterministic Ethernet network using virtual links, each virtual link being associated with a BAG constraint.

The subscriber is characterized by comprising:

-at least one first receiver of a communication port compatible with a communication network;

-at least one first transmitter of a communication port compatible with a communication network;

-at least one first memory provided for recording a configuration table related to a set of virtual links that a subscriber is able to receive and/or forward; and

-a processing unit configured to implement:

-at least one application capable of receiving information from and/or transmitting information to a communication network;

-a screening module;

-a receiving module configured to receive data frames received by the first receiver, for extracting an identifier of the virtual link corresponding to each received data frame, for comparing the identifier with identifiers of virtual links belonging to the configuration table, for accepting the reception and transmitting the data frames to the screening module only if the data frames correspond to virtual links belonging to the set of virtual links; and

a transmitting module comprising a set of transmission queues such that a particular queue belonging to the set of transmission queues is associated with each virtual link of the set of virtual links, the transmitting module being configured to receive data frames from the screening module, to insert each of said data frames in a transmission queue associated with the virtual link corresponding to the data frame, and to send data frames from different transmission queues to the first transmitter while respecting the BAG constraint associated with the corresponding virtual link,

the screening module is configured to receive the data frames transmitted by the receiving module and to transmit the data frames to the application and/or to the transmitting module according to information contained in the configuration table for the virtual link corresponding to each of the data frames.

Thus, given that the first transmitter may forward data frames received by the first receiver, the subscriber may become part of a communication network that does not require a switch: a virtual link that transmits data frames between a transmitter subscriber and a receiver subscriber may pass through one or more intermediate subscribers. This allows avoiding the disadvantages associated with the use of switches in a communication network. Furthermore, in case the transmission module transmits data frames on different virtual links by complying with the BAG constraints corresponding to these virtual links, there is no cumulative effect of jitter when the data frames are propagated on the virtual links between the transmitter subscriber and the receiver subscriber over the communication network. This allows for an easy presentation of the certainty of the communication network. The calculation of the transit time on the virtual link between the transmitter subscriber and the receiver subscriber is simplified: which corresponds to the sum of the delay times (elapsed times) of the subscribers that the virtual link between the transmitter subscriber and the receiver subscriber has elapsed.

According to particular embodiments which may be considered individually or in combination:

-the subscriber is configured to communicate over the communication network according to a communication protocol compatible with part 7 of the ARINC 664 standard;

-the screening module is configured to receive data frames transmitted by the application and to transmit each of said data frames to the transmission module;

-the subscriber further comprises: a second receiver of the communication network compatible communication port and a second transmitter of the communication network compatible communication port, and:

-the receiving module is configured to receive also the data frames received by the second receiver, for extracting the identifier of the virtual link corresponding to each data frame received, for comparing this identifier with the identifiers of the virtual links belonging to the configuration table, for accepting this reception only if the data frame corresponds to a virtual link belonging to the set of virtual links, and for transmitting these data frames to the screening module; and

-the transmission module is configured to simultaneously send data frames from different transmission queues to the first and second transmitters while respecting the BAG constraints associated with the corresponding virtual links.

Advantageously, when the subscriber comprises a second receiver and a second transmitter, the receiving module is configured to extract an identifier corresponding to each received data frame for verifying whether the identifier has been recorded in the second memory of the subscriber, so as to accept the received data frame and record the identifier in the second memory only if the identifier is not recorded in the second memory. This allows redundancy of communication to be achieved using the second transmitter and the second receiver.

The invention also relates to an onboard communication network of a vehicle, which is a deterministic ethernet network using virtual links. The communication network is characterized by comprising a set of subscribers as described above.

According to a first variant, the subscribers of said set of subscribers are connected to each other according to a linear topology.

According to a second variant, the subscribers of said set of subscribers are connected to each other according to a ring topology.

According to a first embodiment of the second variant, when a subscriber of the set of subscribers comprises the second receiver and the second transmitter, said set of subscribers comprises at least a first subscriber, a second subscriber, a third subscriber, a fourth subscriber, and a fifth subscriber, the first subscriber connecting to the other subscribers of said set of subscribers such that: the first receiver of the first subscriber is connected to the first transmitter of the second subscriber, the first transmitter of the first subscriber is connected to the first receiver of the third subscriber, the second receiver of the first subscriber is connected to the second transmitter of the fourth subscriber, and the second transmitter of the first subscriber is connected to the second receiver of the fifth subscriber. Advantageously, furthermore, the first receiver of the second subscriber is connected to the first transmitter of the fourth subscriber and the first transmitter of the third subscriber is connected to the first receiver of the fifth subscriber.

According to a second embodiment of the second variant, when a subscriber of the set of subscribers comprises a second receiver and a second transmitter, the set of subscribers comprises at least a first subscriber, a second subscriber and a third subscriber, the first subscriber connecting to other subscribers of the set of subscribers such that: the first receiver of the first subscriber is connected to the first transmitter of the second subscriber, the first transmitter of the first subscriber is connected to the first receiver of the third subscriber, the second receiver of the first subscriber is connected to the second transmitter of the third subscriber, and the second transmitter of the first subscriber is connected to the second receiver of the second subscriber.

According to a particular embodiment, the communication network further comprises at least one switch to which at least one subscriber of said set of subscribers is connected.

The invention also relates to an aircraft comprising a communication network as described above.

Drawings

The invention will become more apparent upon reading the following description with reference to the accompanying drawings.

Fig. 1 shows a simplified illustration of an aircraft comprising a communication network.

Fig. 2 schematically shows the modular structure of a subscriber of a communication network according to an embodiment of the invention.

Fig. 3, 4, 5, 6, and 7 show different examples of communication networks according to embodiments of the present invention.

Detailed Description

The subscriber 10 shown in fig. 2 is a subscriber of a vehicle-borne communication network, which is a deterministic ethernet network using virtual links, each virtual link being associated with a BAG constraint. The subscriber includes: a first receiver 20a of a communication port compatible with the communication network (name RI on the figure), and a first transmitter 22a of a communication port compatible with the communication network (name T1 on the figure). It also comprises a first memory 19 (the name MEM1 in the figure). The first memory is provided to record a configuration table associated with a set of virtual links that a subscriber may receive and/or forward. The configuration table comprises a list of virtual links that a subscriber can receive and/or forward, said list comprising a set of information for each virtual link comprised by the configuration table: for example, an identifier of the virtual link, such as a number, and information indicating that the subscriber 10 is a receiver of the virtual link and/or that the virtual link should be forwarded by the subscriber 10. The subscriber 10 also includes a receiving module 12 (named "receive" on the figure), a transmitting module 14 (named "send" on the figure), a screening module 16, and at least one application 18. The receiving module, the transmitting module, the screening module, and the application may be implemented in software, for example, by means of a processing unit (e.g., a microprocessor or microcontroller) of the subscriber 10. The subscriber 10 may correspond in particular to a computer of a vehicle loaded with a communication network, which may be a computer dedicated to specific functions of the aircraft: it may for example correspond to a flight management computer of the FMS (flight management system) type, to a flight control computer of the FCS (flight control system) type, to an alert management computer of the FWC (flight alert system) type, to a central maintenance computer of the CMS (central maintenance system) type, etc. The at least one application 18 is therefore responsible for the implementation of the specific function of the aircraft. The computer may thus be a modular avionics computer of the IMA (integrated avionics module) type, able to accommodate a plurality of functions of the aircraft. Said at least one application 18 thus corresponds to one of said functions of the aircraft, and the computer corresponds to the subscriber 10, able to comprise the same number of applications 18 as the functions it houses. Such a computer, whether of the proprietary analog or IMA type, may be located in particular in an avionics cabinet 2 of an aircraft 1, as shown in fig. 1. The avionics cabinet 2 is typically located in the vicinity of the cockpit 3 of the aircraft.

The screening module 16 is connected at an input to the receiving module 12 by a link 24. The application 18 is connected at an input to the screening module 16 via 28. The screening module 16 is connected at an input via a link 29 to the application 18. The transfer module 14 is connected at an input via a link 25 to the screening module 16.

Links

24, 28, 29, and 25 need not be physical links. In particular, these links may correspond to any method of information transfer between modules within a computer (common memory sharing, queues, etc.). The transmit module 14 includes a set of transmit queues F1, F2,. Fk (in the figure, team 1, team 2,......... k, respectively), each associated with a different virtual link.

In operation, when the first receiver 20a of the subscriber 10 receives a data frame, the receiving module 12 receives the data frame and it extracts the identifier of the virtual link corresponding to the frame. The identifier may for example correspond to a virtually linked number. The receiving module compares this identifier with the identifiers of the virtual links belonging to the configuration table recorded in the first memory 19. If the identifier corresponds to a virtual link belonging to the configuration table, the receiving module accepts the reception of the data frame because the following virtual links are involved: whose subscriber 10 is the receiver and/or which subscriber 10 should forward. The receiving module then transmits the data frame to screening module 16 via link 24. In the opposite case, the subscriber 10 is not a virtually linked receiver and should not forward data frames: thus, the receiving module discards the data frame.

When the screening module receives a data frame from the receiving module, it verifies the information contained in the configuration table for the virtual link corresponding to the data frame. If a virtual link involving subscriber 10 as a receiver is involved, the screening module sends a data frame to application 18 via link 28. If a virtual link is involved, which the subscriber 10 should forward, the screening module sends data frames to the transport module via the link 25. Further, application 18 may wish to send data frames over a communication network on a virtual link where subscriber 10 is the transmitter. To this end, the application 18 transmits the corresponding data frames to the screening module via the link 29, and the screening module transmits these data frames to the transmission module via the link 25.

When transmit module 14 receives a data frame from the filter module via link 25, transmit module 14 inserts the data frame into one of transmit queues F1, F2,. fwdarw, Fk associated with the virtual link corresponding to the data frame. The transmit module sends data frames from different transmit queues F1, F2. The first transmitter transmits the data frames over a communication network. The transfer module thus enables a time shaping (flow shaping) of the data flow transmitted by the transmitter 22 a. This time shaping is implemented similarly to the time shaping typically implemented in subscribers of deterministic switched ethernet communication networks using virtual links when they transmit data frames on these virtual links. Thus, by means of the transmission module 14, the time shaping, and therefore the adherence to the BAG constraints, not only relates to the data frames initially transmitted by the subscriber 10 (data frames from the application 18), but also to the data frames received by the first receiver 20a and forwarded by the subscriber 10 (according to the configuration table recorded in the first memory 19). This allows for a reduction of jitter on each virtual link as it is forwarded by a subscriber, such as subscriber 10 (instead of being forwarded by the switch). On the other hand, this also allows for ease of demonstrating the certainty of the communication network, since the virtual link is reshaped in time each time it is received and forwarded by a subscriber of the communication network, such as subscriber 10.

In particular embodiments, subscriber 10 also includes a second receiver 20b (designated as R2 in the figure) of a communication port compatible with the communication network and a second transmitter 22b (designated as T2 in the figure) of a communication port compatible with the communication network. When a data frame is received by the second receiver 20b of the subscriber 10, the receiving module 12 receives the data frame and either transmits the data frame to the screening module or discards the data frame, in the same manner as the data frame received by the first receiver 20 a. Transmit module 14 simultaneously sends data frames from different transmit queues F1, F2,. Fk to first transmitter 22a and second transmitter 22b while adhering to BAG constraints associated with the virtual links corresponding to these transmit queues. The first transmitter and the second transmitter transmit the data frames over a communication network. Advantageously, the subscriber 10 comprises a second memory 21 (name MEM2 in the figure) and the receiving module 12 is further configured to extract the identifier corresponding to each received data frame, to verify whether the identifier is already recorded in the second memory 21, to transmit the received data frame to the screening module only in case the identifier is not recorded in the second memory, and to record the identifier in the second memory. The identifier corresponding to each data frame may in particular correspond to the sequence number of the data frame on the virtual link under consideration. Such a function allows managing the redundant transmission of data frames over a communication network: in the case where the same data frame of a virtual link is transmitted by both the first transmitter and the second transmitter of the transmitting subscriber, the data frame is directed to multiple paths on the communication network (corresponding to different links between subscribers of the communication network). When the subscriber receives the data frame (whether the subscriber is a virtually linked receiver or is solely responsible for forwarding the virtual link), the subscriber's receive module accepts only the first occurrence of the data frame received by the subscriber's first or second receiver. If the data frame is received a second time by the subscriber, in particular by the other of the first or second receiver, it is discarded by the receiving module because it has the same identifier as the previously received and accepted data frame.

Fig. 3 shows a communication network 4 comprising a set of

subscribers

10a, 10 b. The different subscribers of the subscriber set are connected to each other according to a ring network topology, that is to say, a topology such as: the first transmitter (name T1) of each subscriber is connected through a communication link to a first receiver (name R1) of another subscriber, called the next subscriber. The communication link may be of a wired type, an optical fiber type, etc., depending on the communication topology of the communication network. A subscriber of a subscriber set may thus transmit a data frame to any other subscriber of the subscriber set on a virtual link defined therefor. For example, subscriber 10a may transmit data frames to subscriber 10 e. To this end, a virtual link is defined between subscriber 10a (transmitter) and subscriber 10e (receiver). The virtual link passes through

subscribers

10b, 10c, and 10 d. The configuration table of any of

subscribers

10b, 10c, and 10d is configured such that the subscriber in question forwards the virtual link. The configuration table of subscriber 10e is configured such that the subscriber is a virtually linked receiver. Although the example is described in the context of a single receiving subscriber, multiple receiving subscribers of a virtual link may be provided.

In the communication network shown in fig. 4, each of the

subscribers

10a, 10b,. 10h further comprises a second transmitter (name T2) and a second receiver (name R2). The link between the first transmitter and the first receiver of different subscribers is similar to the link described with reference to fig. 3. Further, the second transmitter of each subscriber is connected to the second receiver of the subscriber after the next subscriber. For example, the offer considers subscriber 10c, the next subscriber is subscriber 10d and the subscriber behind subscriber 10d is subscriber 10 e. Thus, a first transmitter of subscriber 10c is connected to a first receiver of subscriber 10d, and a second transmitter of subscriber 10c is connected to a second receiver of subscriber 10 e. In a similar manner, by considering the first and second receivers of subscriber 10c, the first transmitter of subscriber 10b is connected to the first receiver of subscriber 10c and the second transmitter of subscriber 10a is connected to the second receiver of subscriber 10 c. Such a configuration of the communication network allows ensuring redundancy of the communication. Thus, for example, in the case of a designated virtual link between subscriber 10a (transmitter) and subscriber 10e (receiver), even if the link between the first transmitter of subscriber 10b and the first receiver of subscriber 10c is no longer available, communication between subscriber 10a and subscriber 10e is still possible: the data frames corresponding to this virtual link are also transmitted by the second transmitter of subscriber 10a, which are received by the second transmitter of subscriber 10a, which allows overcoming the communication link failure between the first transmitter of subscriber 10b and the first receiver of subscriber 10 c. In addition, the data frame received by subscriber 10b corresponding to the virtual link is also transmitted by the second transmitter of subscriber 10b to the second receiver of subscriber 10 d. This also allows communication link failures between the first transmitter of subscriber 10b and the first receiver of subscriber 10c to be overcome for the virtual link. The communication network configuration is also robust to failures of subscribers of the communication network. Thus, in the case of a designated virtual link, assuming for example that subscriber 10c fails, the data frame received by port 10b corresponding to the virtual link is also transmitted by the second transmitter of subscriber 10b to the second receiver of subscriber 10d, and communication over the virtual link is not interrupted. The link between the second transmitter of subscriber 10b and the second receiver of subscriber 10d allows bypassing of the failed subscriber 10 c.

In the communication network shown in fig. 5, each of the

subscribers

10a, 10b,. 10h further comprises a second transmitter (name T2) and a second receiver (name R2). The link between the first transmitter and the first receiver of different subscribers is similar to the link described with reference to fig. 3. Further, the second transmitter of each subscriber is connected to the second receiver of the previous subscriber on the ring topology. The subscribers before the considered subscriber are defined as the following subscribers: its first transmitter is linked to the first receiver of the considered subscriber. Thus, for example, the second transmitter of subscriber 10b is linked to the second receiver of subscriber 10 a. Such a communication network configuration allows ensuring redundancy of communication, as shown in the example of fig. 4. Preferably, for this purpose redundant virtual links of the virtual links under consideration are defined, which are defined in a ring topology opposite to the virtual links under consideration and passing through the second transmitter and the second receiver of the subscriber. Thus, for example, in the case of a designated virtual link between subscriber 10a (transmitter) and subscriber 10e (receiver), a redundant virtual link between subscriber 10a and subscriber 10e may be defined that passes through

subscribers

10h, 10g, and 10 f. Furthermore, such a topology may allow for a shorter link between the transmitting subscriber and the receiving subscriber. This topology allows for a link through subscriber 10h, for example, when subscriber 10a should send a data frame to subscriber 10 g. The link is shorter than the links traversed by

subscribers

10b, 10c, 10d, 10e and 10 f.

The communication network shown in fig. 6 is similar to that shown in fig. 4, except that subscriber 10d is replaced by two

redundant switches

30a and 30b (named SWa and SWb, respectively) of a conventional deterministic switched ethernet network.

Conventional subscribers

32a, 32b and 32c are connected to the two redundant switches, respectively. The communication network thus comprises two parts: a first portion corresponding to a conventional network comprising two redundant switches and

conventional subscribers

32a, 32b and 32 c; a second part comprising a set of

subscribers

10a, 10b, 10c, 10e, 10f, 10g and 10h as described before, which communicate with each other without a switch. The subscribers of the set of subscribers are interoperable with regular subscribers. The same virtual link may be used for one portion traversed by subscribers of the set of subscribers and for another portion traversed by the conventional redundant switch up to (or from) one or more conventional subscribers.

The communication network shown in fig. 7 comprises a set of

subscribers

10a, 10 b.. 10g, each

subscriber

10a, 10 b.. 10g being similar to the subscriber 10 described with reference to fig. 2. The different subscribers of the set of subscribers are connected to each other according to a linear network topology (daisy chain). The communication links between different subscribers are such that a first transmitter of one subscriber is linked to a first receiver of a next subscriber and a second transmitter of one subscriber is linked to a second receiver of a previous subscriber. This allows for two-way communication between all subscribers of the communication network. Advantageously, although not mandatory, a subscriber at one end of the linear topology is linked to a switch of a conventional deterministic switched ethernet network. Thus, as shown in fig. 7, the subscriber 10a is connected to the switch 30 (name SW in the figure).

Conventional subscribers

32a, 32b and 32c are connected to switch 30. In such a case, the linear topology may be used, for example, to connect a set of transmitters (corresponding to

subscribers

10a, 10 b.. 10g) to a conventional deterministic switched ethernet network at less cost.

In particular embodiments, the subscribers are configured to communicate over the communications network according to a communications protocol compatible with part 7 of the ARINC 664 standard.

Claims

1. Subscriber device of an onboard communication network of a vehicle, the communication network being a deterministic Ethernet network using virtual links, each virtual link being associated with a constraint called bandwidth allocation gap BAG constraint, the constraint relating to the time interval between two successive transmissions of a data packet on the virtual link,

the subscriber device includes:

at least one first receiver of a communication port compatible with a communication network;

at least one first transmitter of a communication port compatible with a communication network;

at least one first memory for recording a configuration table relating to a set of virtual links that a subscriber device is capable of receiving and/or forwarding; and

a processing unit configured to implement:

at least one application capable of receiving information from and/or transmitting information to a communication network;

a screening module;

a receiving module configured to receive data frames received by the first receiver, extract an identifier of a virtual link corresponding to each received data frame, compare the identifier with identifiers of virtual links belonging to the configuration table, accept only the reception of data frames corresponding to virtual links of the set belonging to a virtual link and transmit these data frames to the screening module; and

a transmit module comprising a set of transmit queues, wherein a particular queue belonging to the set of transmit queues is associated with each virtual link in the set of virtual links, the transmit module configured to receive a data frame from the filter module, insert each of the data frames in a transmit queue associated with the virtual link corresponding to the data frame, and send data frames from different transmit queues to the first transmitter while respecting a BAG constraint associated with the corresponding virtual link,

the screening module is configured to receive data frames transmitted by the receiving module and to transmit the data frames to the application and/or to the transmitting module according to information contained in a configuration table for a virtual link corresponding to each of the data frames, and the subscriber device further comprises a second receiver of a communication port compatible with the communication network and a second transmitter of a communication port compatible with the communication network, wherein the subscriber device is coupled to a set of subscriber devices each comprising the first and second transmitters and the first and second receivers, wherein the set of subscriber devices comprises at least a first subscriber device, a second subscriber device, a third subscriber device, a fourth subscriber device, and a fifth subscriber device, the first subscriber device being connected to other subscriber devices of the set of subscriber devices such that: the first receiver of the first subscriber device is connected to the first transmitter of the second subscriber device, the first transmitter of the first subscriber device is connected to the first receiver of the third subscriber device, the second receiver of the first subscriber device is connected to the second transmitter of the fourth subscriber device, and the second transmitter of the first subscriber device is connected to the second receiver of the fifth subscriber device.

2. A subscriber device according to claim 1, wherein the subscriber device is configured to communicate over the communications network according to a communications protocol compatible with part 7 of the ARINC 664 standard, ARINC being an airline radio company.

3. The subscriber device of claim 2, wherein the screening module is configured to receive data frames transmitted by an application and transmit each of the data frames to the transmission module.

4. The subscriber device of claim 1, wherein:

the receiving module is configured to also receive data frames received by the second receiver, extract an identifier of the virtual link corresponding to each received data frame, compare the identifier with identifiers of virtual links belonging to the configuration table, accept only the reception of data frames corresponding to virtual links of the set belonging to a virtual link, and transmit these data frames to the screening module; and

the transmit module is configured to send data frames from different transmit queues to both the first transmitter and the second transmitter while adhering to a BAG constraint associated with a corresponding virtual link.

5. The subscriber device of claim 4, wherein the receiving module is configured to extract an identifier corresponding to each received data frame, verify whether the identifier is already recorded in the second memory of the subscriber device, accept the received data frame and record the identifier in the second memory only if the identifier is not recorded in the second memory.

6. An on-board communication network for a vehicle, the communication network being a deterministic ethernet using virtual links, comprising a set of subscriber devices: wherein each subscriber device of said set of subscriber devices comprises a subscriber device of an onboard communication network of the vehicle, the communication network being a deterministic Ethernet network using virtual links, each virtual link being associated with a constraint called bandwidth allocation gap, BAG, constraint relating to a time interval between two successive transmissions of a data packet on the virtual link,

the subscriber device includes:

a processing unit configured to implement:

a screening module;

a transmit module comprising a set of transmit queues, wherein a particular queue belonging to the set of transmit queues is associated with each virtual link in the set of virtual links, the transmit module being configured to receive data frames from the filter module, insert each of the data frames in a transmit queue associated with the virtual link corresponding to the data frame, and send the data frames from a different transmit queue to the first transmitter while respecting the BAG constraint associated with the corresponding virtual link, the filter module being configured to receive the data frames transmitted by the receive module and transmit the data frames to the application and/or to the transmit module according to information contained in a configuration table for the virtual link corresponding to each of the data frames,

each subscriber device of the communication network further comprises a second receiver of the communication port compatible with the communication network and a second transmitter of the communication port compatible with the communication network, and

wherein the set of subscriber devices includes at least a first subscriber device, a second subscriber device, a third subscriber device, a fourth subscriber device, and a fifth subscriber device, the first subscriber device being connected to other subscriber devices in the set of subscriber devices such that: the first receiver of the first subscriber device is connected to the first transmitter of the second subscriber device, the first transmitter of the first subscriber device is connected to the first receiver of the third subscriber device, the second receiver of the first subscriber device is connected to the second transmitter of the fourth subscriber device, and the second transmitter of the first subscriber device is connected to the second receiver of the fifth subscriber device.

7. The communication network of claim 6, wherein:

the transmit module is configured to send data frames from different transmit queues to both the first transmitter and the second transmitter while adhering to a BAG constraint associated with a corresponding virtual link; and

wherein the subscriber devices in the set of subscriber devices are connected to each other according to a linear topology.

8. A communications network as claimed in claim 7, wherein the receiving module is configured to extract an identifier corresponding to each received data frame, to verify whether the identifier has been recorded in the second memory of the subscriber device, to accept a received data frame and to record the identifier in the second memory only if the identifier is not recorded in the second memory.

9. A communications network according to claim 6, wherein the subscriber devices in the set of subscriber devices are connected to each other according to a ring topology.

10. The communication network of claim 9, wherein:

11. A communications network according to claim 9, wherein the receiving module is configured to extract an identifier corresponding to each received data frame, verify whether the identifier has been recorded in the second memory of the subscriber device, accept a received data frame and record the identifier in the second memory only if the identifier is not recorded in the second memory.

12. The communication network of claim 11, wherein the first receiver of the second subscriber device is connected to the first transmitter of the fourth subscriber device and the first transmitter of the third subscriber device is connected to the first receiver of the fifth subscriber device.

13. The communication network of claim 10, wherein:

14. A communications network according to claim 13, wherein the receiving module is configured to extract an identifier corresponding to each received data frame, to verify whether the identifier has been recorded in the second memory of the subscriber device, to accept a received data frame and to record the identifier in the second memory only if the identifier is not recorded in the second memory.

15. The communication network of claim 6, further comprising at least one switch to which at least one of the set of subscriber devices is connected.

16. An aircraft comprising a communication network according to claim 6.